assessment of variability of rice (oryza sativa l ... · frequency distribution for 29 qualitative...
TRANSCRIPT
Assessment of Variability of Rice (Oryza sativa L.) Germplasm using Agro-morphological Characterization
A. K. Sarawgi*, L. V. Subba Rao, M. Parikh, B. Sharma and G. C. Ojha
Department of Genetics and Plant Breeding
Indira Gandhi Krishi Vishwavidhalaya, Raipur (Chhattisgarh)
Abstract
The present study was carried out to
characterize seven hundred eighty-two rice
germplasm accessions on the basis of
twenty-nine morphological and eight
agronomical traits. Most of the
morphological characters showed variation
in different accessions except leaf : collar
leaf : ligule and leaf : shape of ligule. A
significant amount of variation was
displayed for most of the agronomical traits
examined. After evaluation of 782
accessions for eight quantitative characters,
on the basis of mean values, top ten
accessions were identified for the yield
ancillary traits. These can be used to
identify phenotypically divergent sources
for traits of interest in breeding
programmes.
Key Words: Agro-morphological characters,
germplasm, variability, rice
Rice (Oryza sativa L.) is the world’s most
important cereal crop and serves as the
primary source of staple food for more than
half of the global population (Emani et al.,
2008). The large scale spread of modern, high
*Corresponding author: [email protected]
yielding varieties has replaced the traditional
varieties especially in the irrigated rice
ecosystem leading to reduced genetic base and
thus increased genetic vulnerability. In past
few decades, increase in share of high yielding
varieties and shrinkage in the area of local
varieties have been reported in India (Hore
2005; Rana et al., 2009) as well as in several
other countries (Chaudhary et al., 2006; Itani,
1993). There is an urgent need to broaden
the genetic base of the important crop by
introgressing genes from diverse sources.
Thus, there is a need to collect, exploit and
evaluate the untapped germplasm. In this
context, an attempt was made to characterize a
set of rice germplasm accessions for different
morphological and agronomic trials and to
identify the variability available in the
collection.
Materials and Methods
The material for the present investigations
consisted of 782 rice germplasm accessions
received from DRR Hyderabad and was
evaluated under Multi location trial (MLT)
during kharif 2011 at IGKV, Raipur. Each
entry was sown in a plot comprising three
rows having three meter length at spacing of
20 cm between rows and 15 cm between
plants. The recommended agronomical
practices were followed to raise good crop in
the season. Observations were recorded on
five randomly chosen plants of each accession
for thirty-seven morphological and
agronomical traits. The traits studied were
Basal leaf: sheath colour, Leaf: intensity of
green colour, Leaf: anthocyanin colouration,
Leaf sheath: anthocyanin colouration, Leaf
sheath: intensity of anthocyanin colouration,
Leaf: pubescence of blade surface, Leaf:
auricles, Leaf: anthocyanin colouration of
auricles, Leaf: collar, Leaf: anthocyanin
colouration of collar, Leaf: ligule, Leaf: shape
of ligule, Leaf: colour of ligule, Culm: attitude,
time of 50% heading, Flag leaf: attitude of
blade, Lemma: anthocyanin colouration of
keel, Lemma: anthocyanin colouration of area
below Apex, Lemma: anthocyanin colouration
of apex, Spikelet: colour of stigma, Stem:
length, Stem: anthocyanin colouration of
nodes, Stem: intensity of anthocyanin
colouration of nodes, Stem: anthocyanin
colouration of internodes, Panicle: length of
main axis, Panicle: curvature of main axis,
Panicle: number per plant, Lemma and palea:
colour, Panicle: awns, Panicle: presence of
secondary branching, Panicle: attitude of
branches, Panicle: exsertion, Time of maturity,
Grain: weight of 100 fully developed grains,
Grain: length, Grain: width and Decorticated
grain: colour. Accessions were characterized
using morpho-agronomic descriptors
according to DUS guidelines (DRR, 2006).
Frequency distribution was computed to
categorize the accession into different classes.
Simple statistics (means, ranges) was
calculated to have an idea of the level of
variation.
Results and Discussion
(A) Morphological characterization:
Qualitative characters are important for plant
description (Kurlovich, 1998) and mainly
influenced by the consumers preference, socio-
economic scenario and natural selection (Hien
et al., 2007). Frequency distribution for 29
qualitative traits is depicted in Table 1 and its
graphical representation of frequency
distribution showed in Figure 1. Most of the
morphological characters showed variation in
different accessions except Leaf:collar, Leaf
:ligule and Leaf : shape of ligule. A majority
of accessions were found to possess Basal leaf:
sheath colour (72% green), Leaf: intensity of
green colour (60% dark green), Leaf:
anthocyanin colouration (90% absent), Leaf
sheath: anthocyanin colouration (82 % absent),
Leaf sheath: intensity of anthocyanin
colouration (83% very weak), Leaf:
pubescence of blade surface (57% medium),
Leaf: auricles (99.9% present), Leaf:
anthocyanin colouration of auricles (59% light
purple), Leaf: anthocyanin colouration of
collar (90% absent), Leaf: colour of ligule
(58% white), Culm: attitude (69% semi erect),
Flag leaf: attitude of blade (75% semi erect),
Lemma: anthocyanin colouration of keel (88%
absent/very weak), Lemma: anthocyanin
colouration of area below Apex (87% absent),
Lemma: anthocyanin colouration of apex
(72% absent), Spikelet: colour of stigma (68%
white), Stem: anthocyanin colouration of
nodes (94% absent), Stem: intensity of
anthocyanin colouration of nodes (53%
medium), Stem: anthocyanin colouration of
internodes (875 absent), Panicle: curvature of
main axis (57% semi erect), Lemma and palea:
colour (69.5% straw), Panicle: awns (91%
absent), Panicle: presence of secondary
branching (99% present), Panicle: attitude of
branches (49.5% semi erect to spreading),
Panicle: exsertion (57% well exserted) and
Decorticated grain: colour (74% white).
Similar type of work was also reported by
Bisne and Sarawgi (2008) and Moukoumbi et
al. (2011). Based on the morphological
descriptors 782 accessions were classified for
29 characters. Some of the unique accessions
with distinct features are presented in Table 2.
(B) Agronomical characterization:
Rice accessions were evaluated for
agronomical traits viz., time of 50% heading,
Stem: length, Panicle: length of main axis,
Panicle: number per plant, Time of maturity,
Grain: weight of 100 fully developed grains,
Grain: length, Grain: width from five
competitive plants of middle row of each
entry.
Time to 50 % heading: It had mean value of
110 days and a wider range of 66-157 days.
Almost 50% of the lines fall in the range of
medium to late group (Fig. 2), whereas IC
464013 and IC 577310 accessions were found
to be very early in duration with days to 50%
heading of 66 and 68 days, respectively.
Plant height: It had wider range (73-190 cm)
of variation with a mean value of 144.26 cm.
Ali et al. (2000) have observed relatively
greater range in plant height than the other
characters. Plant height in rice is a complex
character and is the end product of several
genetically controlled factors called internodes
(Cheema et al., 1987). IC 576897 (73 cm) and
IC 576902 (89 cm) were the two accessions
which falls under very dwarf group. More than
50% accessions were having plant height in
the range of 131-150 cm and can be grouped
as tall. Very few accessions exhibited semi
dwarf nature and about 100 accessions showed
semi tall stature. Reduction in plant height
may improve their resistance to lodging and
reduce substantial yield losses associated with
this trait (Abbasi et al., 1995).
Panicle length: It exhibited reasonable amount
of variation with range values of 19-34 cm.
The average panicle length was 27.13 cm long.
Most of the accessions fall under the range of
26-30 cm panicle length. The maximum
panicle length was observed in IC 466454.
Although it contributes positively yet
maximum panicle length is not the only factor
responsible for higher grain yield (Abbasi et
al., 1995). So panicle length alone does not
determine the high grain yield as traits such as
grain size, grain shape, higher number of
tillers/plant, longer panicles and greater
number of grains/panicle ultimately contribute
to higher grain yield (Akram et al., 1994).
Number of productive tillers per plant: It is
another yield attributing trait (Abbasi et al.,
1995). A great variability with high range (2-
19.33) and mean value of 6.01 was exhibited
for number of productive tillers/plant. IC
462373 had maximum value( 19.33).
Days to maturity: It also exhibited high range
(86-184 days) with a mean of 125.02 days IC
464013 had shorter maturity period (86 days)
representing earliness. Minimum value for
days to maturity represents that the variety has
a benefit of early ripening. Most of the lines
fall under mid early followed by medium and
late duration.
100-grain weight: It is also a yield-attributing
trait (Abbasi et al., 1995). Most of the lines
were in the range of 2.1 – 2.5 g. Lines with
high grain weight (> 3g) were also observed in
this set of germplasm (Fig.2). IC 463274 had
maximum 100 grain weight (4.32 g).
Grain length: Grain length is an important
quality parameter. Rice grain can be classified
as extra long, long, medium and short (Akram
et al., 1994). It exhibited high range (6.0-11.8
mm) with mean of 8.4 mm. In the present
material, more than 80% accessions falls in
short to medium group, whereas few of the
accessions were observed with long grain.
IC464907 was observed with maximum grain
length (11.8 mm).
Grain width: It exhibited high range (2-4.4
mm) with mean of 2.6 mm. In the present
material, most of the lines were in the range of
2.1 – 3.0 mm. IC 460013 was observed with
maximum grain width (4.4 mm).
After evaluation of 782 accessions for
eight quantitative characters, on the basis of
mean values, top ten accessions were
identified for the yield ancillary traits (Table
3). IC 462373 (19.33) had the highest number
of effective tillers per plant followed by IC
463424 (14.33). Similarly, IC 463274 (4.32 g)
had the highest rank for 100 grain weight
followed by IC 466455 (4.00 g). Identifying
germplasm accessions for different
agronomical characters in phenotypically
divergent sources would help in prebreeding
and breeding programs.
References
Abbasi, F.M., Sagar, M.A., Akram, M. and Ashraf,
M. 1995. Agronomic and quality traits of
some elite rice genotypes. Pakistan Journal
of Scientific and Industrial Research 38:
348–350.
Akram, M., Abbasi, F.M., Sagar, M.A. and Ashraf,
M. 1994. Increasing rice productivity through
better utilization of germplasm. pp: 107–14.
In: Proc. of a Nat. Semi. on Genetic
Resources of Cereals and their Utilization.
Islamabad, Pakistan.
Ali, S.S., Jafri, S.J.H., Khan, T.Z., Mahmood, A.
and Butt, M.A. 2000. Heritability of yield and
yield components of rice. Pakistan Journal of
Agricultural Research 16: 89–91.
Bisne, R. and Sarawgi, A.K. 2000. Agro-
morphological and quality characterization of
badshah bhog group from aromatic rice
germplasm of Chhattisgarh. Bangladesh
Journal of Agricultural Research 33: 479-
492.
Chaudhary, P., Gauchan, D., Rana, R.B., Sthapit,
B.R and Jarvis, D.I. 2006. Potential loss of
rice landraces from a terai community in
Nepal: a case study from Kachorwa, Bara.
PGR Newsletter 137: 14–21.
Cheema, A.A., Awan, M.A. and Iqbal, J. 1987.
Improvement of Plant Height Architecture in
Basmati Rice. Pakistan Journal of
Agricultural Research 8: 371–4.
Emani, C., Jiang, Y., Miro, B., Hall, T.C. and
Kohali, A. 2008. Transgenic cereals and
forage grasses. In: Compendium of transgenic
crop plants (eds) Kole. C. and Hall, T.C. 1:1-
234
Hien, N.L., Sarhadi, W.A., Hirata, Y. and Oikawa,
Y. 2007. Genetic diversity of morphological
responses and the relationships among Asia
aromatic rice (Oryza sativa L.) cultivars.
Tropics 16: 343–355.
Hore, D.K. 2005. Rice diversity collection,
conservation and management in northeastern
India. Genetic Resources and Crop Evolution
528: 1129–1140.
Itani, T. 1993. History, cultivation and breeding of
aromatic rice varieties. Bull Hiroshima
Prefect Univ 5: 267–281.
19 Journal of Rice Research 2013, Vol. 6 No.1
Kurlovich, B.S., 1998. Species and intraspecific
diversity of white, blue and yellow lupins. Plant
genetic Resource Newsletters 115: 23-32.
Moukoumbi, Y.D., Sie, M., Vodouhe, R., N’dri, B.,
Toulou, B., Ogunbayo, S.A. and Ahanchede, A.
2011. Assessing phenotypic diversity of
interspecific rice varieties using agro-
morphological characterization. Journal of
Plant Breeding and Crop Science 3(5): 74-86.
Rana, J.C., Negi, K.S., Wani, S.A., Saxena, S.,
Pradheep, K., Kak, A., Pareek, S.K. and Sofi,
P.A. 2009. Genetic resources of rice in the
Western Himalayan region of India: current
status. Genetic Resources and Crop Evolution
56: 963–973.
Shobha Rani, N., Subba Rao, L. V. and Viraktamath,
B.C. 2006. National Guidelines for the conduct
of tests for Distinctness, Uniformity and
Stability, Rice. Directorate of Rice Research,
Rajendranagar, Hyderabad.
20 Journal of Rice Research 2013, Vol. 6 No.1
Figure 1: Frequency distribution of important morphological characters
72%
10.9%
17% 0.1%
Basal Leaf: Sheath colour
Green
Light purple
Purple lines
Purple
7%
60%
33%
Leaf: intensity of green colour
Light
Medium
Dark
90%
10%
Leaf: anthocyanin colouration
Absent
Present
82%
18%
Leaf sheath: anthocyanin colouration
Absent
Present
83%
7% 7%
2%
1%
Leaf sheath: intensity of anthocyanin colouration
Very weak
Weak
Medium
Strong
Very strong
0.4% 6%
57%
29%
7.6%
Leaf: pubescence of blade surface
Absent
Weak
Medium
Strong
Very strong
21 Journal of Rice Research 2013, Vol. 6 No.1
0.1%
99.9%
Leaf: auricles
Absent
Present
38%
59%
3%
Leaf: anthocyanin colouration of auricles
Colourless
Light purple
Purple
90%
10%
Leaf: anthocyanin colouration of collar
Absent
Present
58%
41.7%
0.3%
Leaf: colour of ligule
White
Light purple
Purple
7.9%
69%
23% 0.1%
Culm: attitude
Erect
Semi-erect
Open
Spreading
4%
75%
15% 6%
Flag leaf: attitude of blade
Erect
Semi-erect
Horizontal
Drooping
22 Journal of Rice Research 2013, Vol. 6 No.1
88%
4% 4% 3% 1%
Lemma: anthocyanin colouration of keel
Absent/ very weak
Weak
Medium
Strong 87%
3% 3% 5% 2%
Lemma: anthocyanin colouration of area below Apex
Absent
Weak
Medium
Strong
Very strong
72%
2%
3%
8% 15%
Lemma: anthocyanin colouration of apex
Absent
Weak
Medium
Strong
Very strong 68%
0.1%
10% 7%
14.9%
Spikelet: colour of stigma
White
Light green
Yellow
Light purple
Purple
94%
6%
Stem: anthocyanin colouration of nodes
Absent
Present
44%
53%
3%
Stem: intensity of anthocyanin colouration of nodes
Weak
Medium
Strong
87%
13%
Stem: anthocyanin colouration of Internodes
Absent
Present
29.9%
57%
13% 0.1%
Panicle: curvature of main axis
Straight
Semi-straight
Deflexed
Drooping
23 Journal of Rice Research 2013, Vol. 6 No.1
69.5%
7.5%
1% 14%
2% 1%
0.5% 4%
0.5%
Lemma and palea: colour Straw
Gold and gold furrow on straw Brown spots on straw
Brown furrow on straw Brown (Tawny)
91%
9%
Panicle: awns
Absent
Present
1%
99%
Panicle: presence of secondary branching
Absent
Present
0.4% 0.1%
6.5%
49.5%
43.5%
Panicle: attitude of branches
Erect
Erect to semi erect
Semi erect
Semi erect to spreading
13% 30%
57%
Panicle: exsertion
Partly exserted
Mostely exserted
Well exserted 74%
9%
4%
2%
3%
7% 1%
Decorticated grain:colour
White
Light brown
Dark brown
Light red
Red
Purple
24 Journal of Rice Research 2013, Vol. 6 No.1
Figure 2: Frequency distribution of eight quantitative traits in rice accessions
0
100
200
300
400
Nu
mb
er
of
acce
ssio
ns
Time of 50 % heading (days)
0 100 200 300 400 500
Nu
mb
er
of
acce
ssio
ns
Stem : Length (cm)
0
200
400
600
800
< 16 16-20 21-25 26-30 >30
Nu
mb
er
of
acce
ssio
ns
Panicle: length of main axis (cm)
0
200
400
600
800
1000
<11 11-20 > 20
Nu
mb
er
of
acce
ssio
ns
Panicle: number per plant
0
50
100
150
200
250
Nu
mb
er
of
acce
ssio
ns
Time of maturity (days)
0
100
200
300
400
500
<1.5 1.5-2.0 2.1-2.5 2.6-3.0 >3.0
Nu
mb
er
of
acce
ssio
ns
Grain: weight of 100 grains (g)
0
100
200
300
400
500
Nu
mb
er
of
acce
ssio
ns
Grain: length (mm)
25 Journal of Rice Research 2013, Vol. 6 No.1
Table 1: Frequency distribution for agro-morphological characters in rice germplasm
S. No. Morphological characters Colour pattern/ type Frequency
1 Basal leaf: sheath
colour
Green
Light purple
Purple lines
Purple
560
86
135
1
2 Leaf: intensity of green colour Light
Medium
Dark
52
471
259
3 Leaf: anthocyanin colouration Absent
Present
702
80
4 Leaf sheath: anthocyanin colouration Absent
Present
638
144
5 Leaf sheath: intensity of anthocyanin
colouration
Very weak
Weak
Medium
Strong
Very strong
653
52
55
16
6
6 Leaf: pubescence of blade surface Absent
Weak
Medium
Strong
Very strong
3
48
444
226
61
7 Leaf: auricles
Absent
Present
1
781
8 Leaf: anthocyanin colouration of auricles Colourless
Light purple
Purple
295
460
27
9 Leaf: collar
Absent
Present
0
782
10 Leaf: anthocyanin colouration of collar Absent
Present
701
81
11 Leaf: ligule
Absent
Present
0
782
12 Leaf: shape of ligule Truncate
Acute
Cleft/split
0
0
782
13 Leaf: colour of ligule White
Light purple
Purple
454
326
2
14 Culm: attitude
Erect
Semi-erect
Open
Spreading
61
542
178
1
15 Time of heading (50% of plants with
panicles)
Very early (< 71)
Early (71-90)
Medium (91-110)
Late (110-130)
Very late (> 131)
2
319
224
223
14
26 Journal of Rice Research 2013, Vol. 6 No.1
16 Flag leaf: attitude of blade (early
observation)
Erect
Semi-erect
Horizontal
Drooping
33
584
121
44
17 Lemma: anthocyanin colouration of keel Absent/ very weak
Weak
Medium
Strong
Very strong
687
28
30
25
12
18 Lemma: anthocyanin colouration of area
below Apex
Absent
Weak
Medium
Strong
Very strong
682
20
22
42
16
19 Lemma: anthocyanin colouration of apex Absent
Weak
Medium
Strong
Very strong
566
16
20
64
116
20 Spikelet: colour of stigma White
Light green
Yellow
Light purple
Purple
528
1
80
57
116
21 Stem: length (excluding panicle, excluding
floating rice
Very short (< 91 cm)
Short (91-110 cm)
Medium (111-130 cm)
Long (131-150 cm)
Very long (> 150cm)
2
8
107
413
252
22 Stem: anthocyanin colouration of nodes Absent
Present
736
46
23 Stem: intensity of anthocyanin colouration
of nodes
Weak
Medium
Strong
348
413
21
24 Stem: anthocyanin colouration of
Internodes
Absent
Present
684
98
25 Panicle: length of main axis
Very short (< 16 cm)
Short (16-20 cm)
Medium (21-25 cm)
Long (26-30 cm)
Very long (>30m)
0
7
131
592
52
26 Panicle: curvature of main axis Straight
Semi-straight
Deflexed
Drooping
234
449
98
1
27
Panicle: number per plant Few (<11)
Medium (11-20)
Many (> 20)
777
4
1
28 Lemma and palea: colour Straw 544
27 Journal of Rice Research 2013, Vol. 6 No.1
Gold and gold furrow on straw
Brown spots on straw
Brown furrow on straw
Brown (Tawny)
Reddish to light purple
Purple spots/furrow on straw
Purple
Black
60
7
108
13
8
4
33
5
29 Panicle: awns
Absent
Present
708
74
30 Panicle: presence of secondary branching Absent
Present
6
776
31 Panicle: attitude of branches Erect
Erect to semi erect
Semi erect
Semi erect to spreading
Spreading
3
1
53
386
339
32 Panicle: exsertion
Partly exserted
Mostely exserted
Well exserted
99
235
448
33 Time of maturity
Very early (< 100)
Early (101-120)
Medium (121-140)
Late (141-160)
Very late (> 160
133
216
196
172
65
34 Grain: weight of 100 fully developed
Grains
Very low (<1.5g)
Low (1.5-2.0 g)
Medium (2.1-2.5 g)
High(2.6-3.0 g)
Very high (>3.0 g)
18
193
382
146
43
35 Grain: length
Very short (<6.00mm)
Short (6.10-8.50mm)
Medium (8.60-10.50mm)
Long (10.60-12.50mm)
Very long (>12.50mm)
3
467
293
19
0
36 Grain: width
Very narrow ( <2.0mm)
Narrow (2.1-2.5mm)
Medium (2.6-3.0mm)
Broad (3.1-3.5mm)
Very broad (>3.5mm)
7
348
330
78
19
37 Decorticated grain:colour White
Light brown
Variegated brown
Dark brown
Light red
Red
Variegated purple
Purple
Dark purple
582
75
0
31
13
23
0
52
6
28 Journal of Rice Research 2013, Vol. 6 No.1
Table 2: List of unique accessions for different morphological traits.
S. No. Morphological characters Colour pattern/ type Unique accessions 1 Basal leaf: sheath
colour
Purple IC 577118
2 Leaf: auricles
Absent IC 577313
3 Leaf: colour of ligule Purple IC 463034, IC 462482
4 Culm: attitude
Spreading IC 462373
5 Spikelet: colour of stigma Light green IC 450281
6 Panicle: curvature of main axis Drooping IC 466429
7 Lemma and palea: colour
Black IC 463055, IC463190, IC
462453, IC 577162, IC 463796
8 Decorticated grain:colour Dark purple IC 545203, IC 459732, IC
463233, IC 462481, IC 463457,
IC 466621
Table 3: Top ranking accessions for yield ancillary traits.
S.
No.
Plant height
(cm)
Panicle
length (cm)
No. of effective
tillers per plant
Grain length
(mm)
Grain width
(mm)
100 grain
weight (g)
1 IC 576897
(73.00)
IC 466454
(34.00)
IC 462373
(19.33)
IC464907
(11.8)
IC 460013
(4.4)
IC 463274
(4.32)
2 IC 576902
(89.33)
IC 463586
(33.67)
IC 463424
(14.33)
IC 464895
(11.4)
IC 463446
(4.1)
IC 466455
(4.00)
3 IC 577060
(91.67)
IC 462413
(33.33)
IC 462467
(11.67)
IC 463032
(11.4)
IC 466502
(4.0)
IC 576987
(3.83)
4 IC 466394
(96.00)
IC 464906
(33.33)
IC 462256
(10.67)
IC 462498
(11.4)
IC 577035
(3.9)
IC 577061
(3.70)
5 IC 462427
(96.33)
IC 576987
(33.00)
IC 463902
(10.67)
IC 466599
(11.3)
IC 463414
(3.9)
IC 466502
(3.69)
6 IC 576898
(97.00)
IC 577027
(33.00)
IC 463331
(10.33)
IC 545218
(11.2)
IC 463312
(3.8)
IC 466613
(3.65)
7 IC 464979
(105.00)
IC 463212
(33.00)
IC 463400
(10.00)
IC 463214
(11.2)
IC 577488
(3.8)
IC 462498
(3.58)
8 IC 462471
(106.67)
IC 462482
(32.67)
IC 463896
(10.00)
IC 463791
(11.2)
IC 462496
(3.7)
IC 466454
(3.55)
9 IC 463457
(109.00)
IC 463235
(32.67)
IC 463438
(9.67)
IC 463068
(11.2)
IC 462476
(3.7)
IC 463780
(3.52)
10 IC 576900
(109.33)
IC 463643
(32.67)
IC 463367
(9.33)
IRGC21088
(11.2)
IC 463419
(3.7)
IC 463414
(3.48)